JP5994972B2 - Aramid-resin film laminate and method for producing the same - Google Patents

Description

  The present invention is useful as an aramid-resin film laminate excellent in heat resistance, electrical properties, chemical resistance, mechanical properties and the like, and a method for producing the same, particularly as an insulating material for a rotating machine, a transformer, and an electrical / electronic device The present invention relates to an aramid-resin film laminate and a method for producing the same.

Conventionally, a molded body made of a heat-resistant polymer has been used in the electrical insulation field where heat resistance is required. In particular, a molded article using an aromatic polyamide (hereinafter referred to as aramid) is an excellent industrial material having heat resistance, chemical resistance and flame retardancy derived from an aramid molecular structure. Among them, paper composed of a polymetaphenylene isophthalamide fibrid and fiber (trade name Nomex (registered trademark)) is widely used as an electrical insulating paper excellent in heat resistance.
Further, a laminate in which the molded product and a sheet material such as a resin film made of different materials are laminated is also widely used for electrical insulation. By laminating sheet materials of different materials, such a laminate can make use of the properties of the respective sheet materials for the properties of the laminate.

As a method for producing such a laminate, a method of obtaining a laminate by applying an adhesive such as urethane or acrylic on the bonding surface between a heat-resistant sheet material and a resin film (for example, patent document) 1) The method (for example, patent document 2) etc. which apply | coat the melted resin composition on heat-resistant sheet | seat materials by methods, such as extrusion, and form the sheet | seat layer of a resin composition are mentioned.
However, in the former method, the heat resistance of the adhesive is inferior to the heat resistance of the heat-resistant sheet material or resin film, so that the adhesive deteriorates in applications where it is exposed to a high temperature atmosphere for a long time, and the insulation performance is impaired. In the latter method, the above-mentioned problem does not occur because an adhesive is not used, but the resin composition is applied in a melted state, so-called unstretched, low-stretched state. There is a problem that it is inferior in mechanical strength as compared with a laminate in which a resin film stretched on the substrate is bonded.

Japanese Patent No. 4746999 JP 2006-321183 A

  The object of the present invention is to laminate aramid paper and a resin film without using an adhesive and without damaging the properties of both, and aramid having excellent heat resistance, electrical properties, chemical resistance, mechanical properties, etc. A resin film laminate and a method for producing the same are provided.

As a result of intensive studies to solve the above-mentioned problems, the inventors of the present invention have either side of aramid paper composed of aramid fibrids and aramid short fibers, and a surface scanning portion of a differential scanning calorimeter (DSC). By performing plasma treatment on the surface having a heat of fusion of 25 cal / g or less by measurement, and combining the plasma-treated surface and the plasma-treated surface of the resin film, heating, pressing, or heat-pressing processing The present inventors have found that the above problems can be solved, and have completed the present invention.
That is, the first invention of the present application is a method for producing an aramid-resin film laminate in which an aramid paper comprising an aramid fibrid and an aramid short fiber and a resin film are laminated, and any one of the aramid papers The surface of which the heat of fusion measured by a differential scanning calorimeter (DSC) of the surface layer portion is 25 cal / g or less was subjected to plasma treatment, and the plasma-treated surface and the resin film were subjected to plasma treatment. The present invention provides a method for producing an aramid-resin film laminate, which is bonded by heating, pressing, or heating and pressing together with the surfaces.

According to a second invention of the present application, in the aramid-resin film laminate according to the first invention, a plasma surface treatment of the aramid paper is performed, and a porosity of a surface layer of an adhesive surface with the resin film is in contact with the resin film. It is intended to provide an aramid-resin film laminate characterized by being 5% or more higher than the porosity of the surface layer on the non-finished surface.
According to a third invention of the present application, in the aramid-resin film laminate according to the first or second invention, the heat of fusion of the surface layer portion of the surface contacting the resin film of the plasma-treated aramid paper is The present invention provides an aramid-resin film laminate characterized by being 1.0 cal / g or more lower than the heat of fusion of the surface layer portion of the non-contact surface.
According to a fourth invention of the present application, in the aramid-resin film laminate according to any one of the first to third inventions, the plasma-treated aramid paper and the plasma-treated resin film are mediated by an adhesive. The present invention provides an aramid-resin film laminate that is directly laminated without any problem.

According to a fifth invention of the present application, in the aramid-resin film laminate according to any one of the first to fourth inventions, the resin film is any one of polyethylene terephthalate, polyethylene naphthalate, polyimide, polytetrafluoroethylene, or polyphenylene sulfide. Thus, an aramid-resin film laminate is provided.
A sixth invention of the present application is the aramid-resin film laminate according to any one of the first to fifth inventions, wherein the thickness is 0.05 to 1.00 mm. Is to provide.
According to a seventh invention of the present application, in the aramid-resin film laminate according to any one of the first to sixth inventions, the aramid-resin has a three-layer structure of aramid paper-resin film-aramid paper. A film laminate is provided.
In the eighth invention of the present application, an aramid paper composed of an aramid fibrid and an aramid short fiber is calendered between two rolls different by at least 20 ° C., and then plasma-treated on the surface in contact with the low temperature roll, The present invention provides a method for producing an aramid-resin film laminate, characterized by heating, pressurizing, or heat-pressing a plasma-treated aramid paper and a resin-treated surface of a resin film together. .

Hereinafter, the present invention will be described in detail.
[Aramid]
In the present invention, aramid means a linear polymer compound in which 60% or more of amide bonds are directly bonded to an aromatic ring. Examples of such aramid include polymetaphenylene isophthalamide and a copolymer thereof, polyparaphenylene terephthalamide and a copolymer thereof, and copolyparaphenylene 3,4'-diphenyl ether terephthalamide. These aramids are industrially produced by, for example, a solution polymerization method by a condensation reaction with an aromatic acid dichloride and an aromatic diamine, a two-step interfacial polymerization method, etc., and can be obtained as a commercial product. However, the present invention is not limited to this. Among these aramids, polymetaphenylene isophthalamide is preferably used because it has good molding processability, flame retardancy, heat resistance and the like.

[Aramid Five Brid]
In the present invention, an aramid fibrid is a film-like fine particle made of aramid and may be referred to as an aramid pulp. Examples of the production method include those described in JP-B-35-11851, JP-B-37-5732, and the like. Since fibrids have paper-making properties like ordinary wood (cellulose) pulp, they can be formed into a sheet by a paper machine after being dispersed in water. In this case, a so-called beating process can be performed for the purpose of maintaining quality suitable for papermaking. This beating process can be performed by a disk refiner, a beater, or other papermaking raw material processing equipment that exerts a mechanical cutting action. In this operation, the shape change of the fibrid can be monitored with the freeness as defined in JIS P8121. In the present invention, the freeness of the organic compound fibrid after the beating treatment is preferably in the range of 10 to 300 cm ³ (Canadian Standard Freeness). In a fibrid having a freeness greater than this range, the strength of the nonwoven sheet formed therefrom may be lowered. On the other hand, if it is desired to obtain a freeness smaller than 10 cm ³ , the utilization efficiency of the mechanical power to be input becomes small, the processing amount per unit time is often reduced, and further refinement of the fibrid is reduced. Since it proceeds too much, the so-called binder function is likely to deteriorate. Therefore, no particular advantage is recognized even when trying to obtain a freeness smaller than 10 cm ³ .

[Aramid short fiber]
In the present invention, the short aramid fiber is obtained by cutting a fiber made of aramid into a predetermined length. Examples of such a fiber include “Conex (registered trademark)” of Teijin Techno Products Co., Ltd. ”,“ Technora (registered trademark) ”, DuPont“ Nomex (registered trademark) ”,“ Kevlar (registered trademark) ”, Teijin Aramid“ Twaron (registered trademark) ”, etc. It is not something.
The aramid short fibers can preferably have a fineness within a range of 0.05 dtex or more and less than 25 dtex. A fiber having a fineness of less than 0.05 dtex is not preferable because it tends to cause aggregation in the production by a wet method (described later), and a fiber having a fineness of 25 dtex or more is too large in diameter. If the shape has a density of 1.4 g / cm ³ , a diameter of 45 microns or more is not preferable because the aspect ratio is reduced, the mechanical reinforcement effect is reduced, and the uniformity of the aramid paper is deteriorated.
The length of the aramid short fiber can be selected from a range of 1 mm or more and less than 25 mm. If the length of the short fiber is less than 1 mm, the mechanical properties of the aramid paper are degraded. On the other hand, those having a length of 25 mm or more cause “entanglement”, “binding”, etc. during the production of the aramid paper by the wet method described later. It is not preferable because it easily causes defects.

[Aramid paper]
In the present invention, the aramid paper is a sheet-like material mainly composed of the aramid fibrids and the aramid short fibers, and generally has a thickness in the range of 20 μm to 1000 μm. Further aramid paper generally has a basis weight in the range of ^{10g / m 2 ~1000g / m 2} .
Aramid paper is generally produced by a method of mixing the above-mentioned aramid fibrid and aramid short fibers and then forming a sheet. Specifically, for example, after dry blending the aramid fibrid and the aramid short fiber, a method of forming a sheet using an air flow, after the aramid fibrid and the aramid short fiber are dispersed and mixed in a liquid medium, the liquid permeation is performed. For example, a so-called wet papermaking method using water as a medium is preferably selected. .
In the wet papermaking method, a single or mixed aqueous slurry containing at least aramid fibrids and aramid short fibers is fed to a paper machine and dispersed, then dewatered, squeezed and dried to be wound as a sheet. Is common. As the paper machine, a long paper machine, a circular paper machine, an inclined paper machine, and a combination paper machine combining these are used. In the case of production with a combination paper machine, a composite sheet composed of a plurality of paper layers can be obtained by forming and combining slurry having different blending ratios. Additives such as a dispersibility improver, an antifoaming agent, and a paper strength enhancer are used as necessary during papermaking.

[Calendar processing]
The aramid paper obtained as described above can be improved in density and mechanical strength by hot pressing at high temperature and high pressure between a pair of rolls. Examples of the hot pressure conditions include, but are not limited to, a temperature of 10 ° C. to 350 ° C. and a linear pressure of 50 kg / cm to 400 kg / cm in the case of a metal roll. A plurality of aramid papers can be laminated during hot pressing. The above hot pressing can be performed a plurality of times in an arbitrary order.
By calendering aramid paper by the above-mentioned method, the porosity of the paper is lowered and the surface is smoothed. As a result, it is considered that the adhesive force with a resin film described later is lowered. Increasing the adhesion between the aramid paper and the resin film is important in terms of avoiding peeling during use of the aramid-resin film laminate. In the present invention, although the adhesion between the layers is improved by performing plasma surface treatment to be described later, in order to further enhance the effect, the difference in porosity of the surface layer of the aramid paper is set to 5% or more. It has been found that a high adhesive force can be obtained without impairing properties such as the mechanical strength of aramid paper by performing plasma surface treatment on the surface of the higher side and laminating it with a resin film. The surface layer in the present invention refers to a portion of 10 μm in the cross-sectional direction from the outermost surface. Here, the maximum difference in porosity is preferably 70%.
As a method of obtaining an aramid paper in which the difference in porosity between both surface layers is 5% or more, a single calendering process is performed with a roll heated to different temperatures, or one side of the aramid paper is calendered at a certain temperature. Then, a method of performing calendering on the opposite surface at different temperatures is exemplified, but it is not limited thereto. By processing in this way, the porosity of the surface layer of the aramid paper, that is, the porosity can be changed. Furthermore, by applying the plasma surface treatment described later to the surface that is in contact with the low-temperature roll, that is, a more porous surface, the effect of the plasma surface treatment can be further extracted at the time of bonding, and the anchor effect is also achieved. In addition, as a result, it is considered that the adhesion between the layers of the aramid paper and the resin film is improved. In the present invention, when two calender rolls are processed at different temperatures, the temperature difference is at least 20 ° C, preferably 50 ° C, more preferably 100 ° C. Here, the maximum temperature difference is preferably 340 ° C. The temperature of the calender roll having the lower temperature is preferably in the range of 10 to 330 ° C.

[Heat of fusion]
In the present invention, the heat of fusion is measured by a thermal method such as DSC (Differential Scanning Calibration) or DTA (Differential Thermal Analysis). In general, polymers exhibit a wide range of melting behavior, reflecting non-single molecular weight components and differences in the degree of crystallization. In the present invention, the heat of fusion is determined by the area of the endothermic peak obtained by DSC analysis.
It is considered that the heat of fusion per unit solid content of the surface layer of the calendared aramid paper indicates the amount of crystals. In the aramid-resin film laminate of the present invention, the surface of the aramid paper having a surface layer of the surface to be bonded to the resin film has a heat of fusion of 25 cal / g or less so that the surface having a low crystallinity is bonded to the resin film. By combining them, the adhesive strength between the aramid paper and the resin film is increased. However, since aramid paper having a low crystallinity generally tends to have a low mechanical strength, in order to obtain an aramid paper having a surface with a low crystallinity and a high mechanical strength, for example, two calenders are used. By processing the roll with a temperature difference, etc., by applying plasma surface treatment to the surface with lower crystallinity and bonding it to the resin film, the adhesion between the aramid paper and the resin film is further increased. It is considered that characteristics such as mechanical strength can be enhanced. The preferable range of the heat of fusion of the surface layer portion of the surface to be bonded to the resin film is 10 to 25 cal / g.
The heat of fusion of the surface layer portion of the surface that contacts the resin film of the aramid paper is preferably 1.0 cal / g or more lower than the heat of fusion of the surface layer portion of the surface that does not contact the resin film, more preferably 1. It is 2 cal / g or more, more preferably 1.5 cal / g or more. Here, the maximum reduction is preferably 20 cal / g.

[Resin film]
In the present invention, the resin film is a sheet formed by a method such as molding after melting the synthetic resin, or removing the solvent from the synthetic resin solution, and stretching after the sheet is formed. It may be performed or may be left unstretched. The stretched resin film is preferable in terms of high mechanical strength, and the unstretched resin film has a feature such as excellent molding processability. The thickness of the resin film is 2 to 500 μm, preferably 5 to 400 μm, and more preferably 10 to 300 μm.
In the present invention, there is no restriction on the use of a synthetic resin film, but among these, polyethylene terephthalate, polyethylene naphthalate, polyimide, polytetrafluoroethylene, or polyphenylene sulfide is preferable. In any film, by laminating with aramid paper without using an adhesive by the method described later to form an aramid-resin film laminate, it can be used as a material such as an electrical insulating member without impairing the characteristics of each resin film. It can be suitably used.

[Plasma surface treatment]
The plasma surface treatment in the present invention means that the substrate to be treated is exposed to a discharge that starts and continues by applying a high voltage of direct current or alternating current between electrodes, for example, corona discharge under atmospheric pressure or glow discharge in vacuum. Refers to the processing performed by At this time, although not particularly limited, processing in a vacuum with a wide selection of processing gas is preferable. Although it does not specifically limit as process gas, He, Ne, Ar, nitrogen, oxygen, a carbon dioxide gas, air, water vapor | steam etc. are used in the state of individual or mixed. Of these, Ar and carbon dioxide are preferable from the viewpoint of discharge initiation efficiency. The treatment pressure is not particularly limited, but glow discharge treatment in which discharge is sustained in a pressure range of 0.1 Pa to 1330 Pa, so-called low temperature plasma treatment is preferable in terms of treatment efficiency. More preferably, it is the range of 1 Pa-266 Pa.
In the present invention, more specifically, the composition ratio X (O / C) of oxygen atoms (O) and carbon atoms (C) on the aramid paper surface is in the range of 120% or more and 250% or less of the theoretical value. As a result, the desired good heat-fusibility can be obtained. Here, the composition ratio X (O / C) is the ratio of the number of atoms between the number of carbon atoms (C) and the number of oxygen atoms (O) measured on the aramid paper surface by XPS (X-ray electron light spectroscopy). (Measured value). Moreover, the theoretical value means the value of the atomic ratio calculated from the repeating unit of the high molecular chemical structural formula in the resin composition constituting the resin.

For example, in the case of Nomex (registered trademark) paper, polymetaphenylene isophthalamide as a main component is C / O / N = 14/2/2, and the number of carbon atoms (C) and the number of oxygen atoms (O). The theoretical value of the composition ratio X (O / C) is 2/14 = 0.143 based on carbon (C). Usually, since a small amount of hydrocarbon-based material adheres to the surface, the measured value is considered to be smaller than the theoretical value.
According to the study by the present inventors, the composition ratio X (O / C) is in the range of 120% to 250% of the theoretical value, that is, in the range of 20% to 150%, which is larger than the theoretical value. If so, good heat-fusibility could be obtained. More preferably, it is 150% or more and 230% or less of range. If the composition ratio X is less than 120% of the theoretical value, good heat-fusibility cannot be obtained. Moreover, even if it exceeds 250% of the theoretical value, good heat-fusibility cannot be obtained.
Further, as a method for obtaining an aramid paper having the composition ratio X (O / C) within the above-mentioned range, the surface of the aramid paper obtained by the above-described method is subjected to a low-temperature plasma treatment using a low-temperature plasma treatment machine. The method to do can be adopted. Thereby, the aramid paper excellent in heat-fusibility can be obtained.

At this time, in the case where the low temperature plasma processing is performed on the aramid paper using the internal electrode type plasma processing machine, the processing strength (output) of the low temperature plasma processing is 30 W · min / m ^{2 to} 1500 W · min /. A range of m ² is preferable. Thereby, the range of the composition ratio X (O / C) described above on the surface of the aramid paper can be obtained. According to the study by the present inventors, when the intensity of the low temperature plasma treatment is lower than the above range, the above-described composition ratio X becomes small, and when the intensity of the low temperature plasma treatment is higher than the above range, the above composition ratio X In both cases, good heat-sealing property cannot be obtained. More preferably in the range of ^{130W · min / m 2 ~1200W ·} min / m 2.
Further, in the present invention, in order to further improve the adhesion between the aramid paper and the resin film, it is necessary that the surface of the resin film is also subjected to plasma surface treatment. Plasma treatment is preferred. The processing strength (output) in the low-temperature plasma processing can be appropriately selected depending on the type of resin film, the type of processing apparatus to be processed, and the ability. In addition, the apparatus, electrode, process gas, etc. for a low temperature plasma process are not specifically limited, A well-known thing can be used.

[Aramid-resin film laminate]
In the present invention, the aramid-resin film laminate has a layer structure of at least two layers obtained by laminating the aramid paper subjected to the plasma surface treatment and the resin film subjected to the plasma surface treatment. In general, it preferably has a thickness of 0.05 mm to 1.00 mm. More preferably, it is 0.08 mm to 0.90 mm, and further preferably 0.10 mm to 0.85 mm.
As the aramid-resin film laminate of the present invention, any layer structure may be adopted as long as it is within the above-mentioned thickness range, and in particular, an aramid paper-resin film having an aramid paper disposed on the surface thereof. -A three-layer structure of aramid paper is preferable in terms of uniformity in the thickness direction, dimensional stability, and ease of taking advantage of the high heat resistance characteristic of aramid paper.

  Examples of the method for forming an aramid-resin film laminate in the present invention include heat processing, pressure processing, or heat pressure processing, and the like, for example, a method by hot pressing, a method of passing between a pair of heated rolls, Examples of the method include hot air and ultrasonic bonding, but are not limited thereto. At this time, it is desirable from the viewpoints of the mechanical properties and insulating properties of the laminated body that the temperature at the time of forming the laminated body is set to a lower temperature without raising the temperature to the melting point or the vicinity of the decomposition point. Since the aramid-resin film laminate of the present invention is subjected to plasma treatment on the surface of the aramid paper and the resin film, it can obtain good interlayer adhesion without raising the lamination temperature to near the melting point or decomposition point, Thereby, an aramid-resin film laminate can be obtained without impairing the mechanical properties of the resin film. The temperature at which the aramid-resin film laminate is formed is not particularly limited as long as it is sufficiently lower than the melting point, softening point, or decomposition point of the laminated resin film, and the melting point, softening point, Alternatively, considering the decomposition point, a temperature that can sufficiently maintain the mechanical properties of the resin film may be selected.

Hereinafter, the present invention will be described more specifically with reference to examples. These examples are merely illustrative and are not intended to limit the content of the present invention.
[Measuring method]
(1) Weight per unit area, thickness, density Carry out according to JIS C 2300-2, and the density was calculated by (weight per unit area / thickness).
(2) Surface Layer Porosity Using a scanning electron microscope, arbitrarily photographed five cross-sectional photographs of the sheet, the area of the void portion was determined for the 10 μm portion from the outermost surface in the depth direction, and calculated according to the following formula: . This was performed for all five points, and the average value was defined as the surface layer porosity.
(Surface porosity) [%] = (Area of void) / (Area of 10 μm from the outermost surface) × 100
(3) Heat of surface layer melting A measurement sample was collected from the surface layer portion of the sheet, and measured by DSC analysis at a heating rate of 10 ° C./min in a nitrogen atmosphere. Measurement was performed on 5 samples per level, and the average value was defined as the heat of fusion.

(4) Interlaminar adhesive strength The measurement was performed according to JIS C 6481, and the 90 ° peel strength of a sample having a width of 10 mm was measured at a tensile speed of 50 mm / min using a tensile tester.
(5) Bending workability The sample cut | disconnected to width 11mm and length 30cm was inserted in the automatic bending machine (made in-house), the bending process was performed, and bending workability was evaluated. In the evaluation, the presence or absence of a change in appearance such as “floating” or “peeling” in the bent portion was visually determined. Judgment criteria are “Floating”, “Peeling”, etc. that are at a practical level are accepted (○), “Floating”, “Peeling” occur even in part, and those that are not products are not acceptable (×). .

[Raw material preparation]
A polymetaphenylene isophthalamide fibrid was manufactured using a pulp particle manufacturing apparatus (wet precipitator) composed of a combination of a stator and a rotor described in JP-A-52-15621. This was processed with a disaggregator and a beater to prepare a length weighted average fiber length of 0.9 mm. On the other hand, a meta-aramid fiber (Nomex (registered trademark), single yarn fineness 2.2 dtex) manufactured by DuPont was cut into a length of 6 mm to obtain a papermaking raw material.
[Manufacture of calendared aramid paper]
Aramid fibrids and aramid short fibers prepared as described above were each dispersed in water to prepare a slurry. After mixing these slurries so that the blend ratio (weight ratio) of aramid fibrids and aramid short fibers is 1/1, the mixture is fed to a Ford linear paper machine, dehydrated, squeezed and dried. Rolled up to obtain aramid paper. Next, with a metal calender roll, one roll temperature is set to 330 ° C., the other roll temperature is set to 200 ° C., and heated and pressed at a linear pressure of 150 kg / cm. Obtained.
Further, using the above-mentioned aramid paper, this was heat-pressed with a metal calender roll at a temperature of 330 ° C. and a linear pressure of 150 kg / cm to obtain a calendered aramid paper B.

[Production of plasma-treated aramid paper]
The above-mentioned calendered aramid papers A and B were passed through an internal electrode type low-temperature plasma treatment machine described in Japanese Patent No. 4607826 and subjected to low-temperature plasma treatment at a treatment strength of 650 W · min / m ² . At this time, the aramid paper A subjected to calendering was subjected to low-temperature plasma treatment only on the surface in contact with the low-temperature roll to obtain plasma-treated aramid paper C. Moreover, about the aramid paper B by which calendar processing was carried out, the low temperature plasma process was performed only to the arbitrary one side surface, and the aramid paper D by which the plasma surface process was carried out was obtained. At this time, the composition ratio X (O / C) of the number of oxygen atoms (O) and carbon atoms (C) on the plasma-treated aramid paper surface is the theoretical value of the atomic number ratio for both the aramid papers C and D. Of 206%.
[Production of plasma surface-treated resin film]
A polyphenylene sulfide resin (hereinafter referred to as PPS) film (hereinafter referred to as PPS film) having a thickness of 100 μm is passed through an internal electrode type low-temperature plasma treatment machine described in Japanese Patent No. 4,607,826 to obtain a treatment strength of 100 W · min / m ² . Both surfaces of the film were subjected to low-temperature plasma treatment to obtain a plasma-treated PPS film F.

[Example 1]
The two plasma-treated aramid papers C and the plasma-treated PPS film F are laminated with the plasma-treated surfaces so as to form three layers of aramid paper-resin film-aramid paper. The laminates were heated and pressed with a metal calender roll at a temperature of 180 ° C. and a linear pressure of 500 kg / cm to obtain an aramid paper-PPS film laminate. At this time, the surface layer porosity of the aramid paper was 62% for the surface in contact with the resin film and 48% for the surface not in contact with the resin film. The surface layer heat of aramid paper was 21.8 cal / g on the surface in contact with the resin film and 27.6 cal / g on the surface not in contact with the resin film. Table 1 shows the main characteristic values of the aramid paper-PPS film laminate thus obtained.
[Comparative Example 1]
Instead of the aramid paper C, an aramid paper A not subjected to plasma surface treatment was used, and in place of the resin film F, a resin film E not subjected to plasma surface treatment was used, as in Example 1. The aramid paper-PPS film laminate was obtained. At this time, the surface layer porosity of the aramid paper was 59% on the surface in contact with the resin film and 49% on the surface not in contact with the resin film. Moreover, the surface melting heat of the aramid paper was 22.8 cal / g on the surface in contact with the resin film, and 28.4 cal / g on the surface not in contact with the resin film. Table 1 shows the main characteristic values of the aramid paper-PPS film laminate thus obtained.

[Comparative Example 2]
Instead of the aramid paper C, an aramid paper B that has not been subjected to plasma surface treatment is used, and in place of the resin film F, a resin film E that has not been subjected to plasma surface treatment is used. The aramid paper-PPS film laminate was obtained. At this time, the surface layer porosity of the aramid paper was 49% on the surface in contact with the resin film and 48% on the surface not in contact with the resin film. The surface layer heat of fusion of the aramid paper was 26.8 cal / g on the surface in contact with the resin film and 27.2 cal / g on the surface not in contact with the resin film. Table 1 shows the main characteristic values of the aramid paper-PPS film laminate thus obtained.
[Comparative Example 3]
It replaced with the aramid paper C and implemented similarly to Example 1 except having used the plasma-treated aramid paper D, and obtained the aramid paper-PPS film laminated body. At this time, the surface layer porosity of the aramid paper was 50% on the surface in contact with the resin film and 48% on the surface not in contact with the resin film. The surface layer heat of aramid paper was 27.9 cal / g on the surface in contact with the resin film and 28.2 cal / g on the surface not in contact with the resin film. Table 1 shows the main characteristic values of the aramid paper-PPS film laminate thus obtained.

Table 1

  As shown in Table 1, in Example 1 which is the product of the present invention, an aramid-resin film laminate is obtained by applying a plasma surface treatment to a surface of an aramid paper having a heat of fusion of 25 cal / g or less and bonding it together. The interlaminar adhesion strength was high and the bending workability was excellent. On the other hand, Comparative Examples 1 and 2 have low interlayer adhesion between the aramid paper and the resin film, so that “floating” and “peel” easily occur in the bending workability test, and Comparative Example 3 is a comparative example. Although the adhesive strength is improved as compared with 1-2, the bending workability cannot be sufficiently satisfied, for example, the layers are peeled off when wound on a conductor or the like, and are insufficient as an insulating material. Was suggested. Therefore, in order to obtain an aramid-resin film laminate excellent in heat resistance, electrical properties, mechanical properties, etc. useful as an insulating material for rotating machines, transformers, and electrical / electronic devices, the aramids exemplified in the above examples are used. -It has been found effective to use a resin film laminate.

Claims (7)

An aramid- resin film laminate in which an aramid paper made of aramid fibrid and an aramid short fiber and a polyphenylene sulfide resin film or a polyimide resin film are laminated, and is a surface of any one of the aramid paper Plasma treatment is performed on the surface having a heat of fusion of 25 cal / g or less as measured by a differential scanning calorimeter (DSC) of the part, and the plasma-treated surface and the plasma-treated surface of the resin film are combined and heated. An aramid-resin film laminate, which is bonded by pressurization or heat-pressing.   2. The porosity of the surface layer of the surface of the aramid paper that is plasma-treated and bonded to the resin film is 5% or more higher than the porosity of the surface layer of the surface that does not contact the resin film. Aramid-resin film laminate.   The heat of fusion of the surface layer portion of the surface in contact with the resin film of the plasma-treated aramid paper is 1.0 cal / g or more lower than the heat of fusion of the surface layer portion of the surface not in contact with the resin film. 3. The aramid-resin film laminate according to 1 or 2.   The aramid-resin according to any one of claims 1 to 3, wherein the plasma surface-treated aramid paper and the plasma surface-treated resin film are directly laminated without using an adhesive. Film laminate. Thickness is 0.05-1.00 mm, The aramid-resin film laminated body as described in any one of Claims 1-4 characterized by the above-mentioned. Aramid paper - resin films - aramid according to any one of claims 1 to 5, characterized in that it has a three-layer structure of aramid paper - resin film laminate. Aramid paper composed of aramid fibrids and aramid short fibers is at least one side of the aramid paper so that the heat of fusion measured by a differential scanning calorimeter (DSC) of the surface layer portion is 25 cal / g or less. After the calendering between two rolls at 20 ° C., the plasma-treated aramid paper and the plasma-treated surface of the polyphenylene sulfide resin film or polyimide resin film subjected to plasma treatment on the surface in contact with the low-temperature roll; A process for producing an aramid-resin film laminate, characterized by heating, pressurizing, or heating and pressurizing together.